HU189857B - Programmable equipment for monitoring maximum value - Google Patents

Abstract

The present invention relates to a programmable maximum value monitoring device, preferably for controlling the power consumption of simultaneous consumption of power consumption sites on the basis of a performance fee contract, with a timer receiving meter from a power meter of a gas supplier, a time base generating circuit for measuring measurement time intervals, an evaluation unit, an evaluation unit, and an actuator comprising an interlocking and / or signaling element coupled to the output of the evaluation unit. The device according to the invention is that the evaluating unit, when reaching the maximum value specified at the end of a measurement time interval, is provided by a terminal switch (16) providing a switching signal and at least one switch signal (15) at the time of the measurement time intervals, reaching the measurement times, which is proportional to the elapsed time. ). The sub-switch (s) (15) and the terminal switch (16) have a programmable input (29, 30) suitable for setting a counter (23, 30) coupled to the output of the counter (13) and a value comparable to that of the counter (13). ) (15) the parallel input (i) (24) receiving the output (26) of the time base circuit (14) and the programmable input Q (31) suitable for setting the measurement time within the time interval and the partial or complete disconnection of the consumers actuator control outputs (17). The time base circuit (14) is connected to the counter (13) of the counter (13) and the wipe input of the evaluation unit to the wiper relay (11) of the current meter indicating the end of the measurement intervals. -1-

Description

BACKGROUND OF THE INVENTION The present invention relates to a programmable peak value monitoring device, preferably for controlling power consumption at a time interval, based on measurement of average power of time consuming contracts, having a meter for receiving pulses from the power meter's consumption meter, the output of which is an actuator circuit comprising a switch and / or a signaling element.

In order to enable the consumer to use the energy contractually contracted as economically as possible and without the risk of overcharging and paying the associated penalty fee, a device capable of monitoring the quarterly effective average power before the value of the contracted consumption is exceeded is required. consumers, or some of them, from the network.

Maximum guards using electromechanical and electronic principles, such as the AEG and SIEMENS maximum value controllers (Höchstlastwaechter, Maximumwaechter) are known for solving this task. The disadvantages of electromechanical solutions are due to the use of moving parts, whose wear and tear adversely affects the life of such devices and also limits their operating speed.

The circuit arrangement described in Hungarian Patent Publication No. 155093 seeks to overcome the drawbacks of the aforementioned electromechanical systems using digital technology. This solution compares the sum of the impulses received during a quarter hour to an adjustable program. The program is interchangeable in the device and is therefore relatively easy to convert to different modes (winter, summer, morning, afternoon), but the new mode can only be set.

Hungarian Patent Application No. 165103 discloses an electronic device constructed from digital circuits for controlling and / or controlling processes characterized by maxima, which, by means of forward, backward, multiplier and summing circuits, can determine the consumption impulses expected at the end of the time interval at any time during the measurement period. provided that the power on does not change in the meantime. If there is a risk of overconsumption, the intervention can be delayed, for example, until the consumption reaches 50% of the allowable pulse amount. However, this device does not provide a solution for setting or changing the various modes. The solutions described are, on the one hand, complicated in circuitry and, on the other hand, do not allow automatic switching between different modes (pL daytime and peak time).

It is an object of the present invention to provide a device which eliminates the drawbacks of known solutions, yet is simple in design, highly reliable and inexpensive. It is also an object of the invention to provide automatic switching between the various modes of operation, thereby ensuring full unattended operation and synchronous operation with the main meter of the power supply.

The present invention is based on the discovery that automatic switching between different modes can be accomplished by providing the programmable unit with a plurality of programmable inputs for adjusting a value to be compared with the number of consumption pulses over a period of time and selecting them with a signal from the power meter. thus ensuring synchronous operation of the meter and the maximum value monitor.

The object of the present invention is achieved, in the most general sense, by providing an apparatus in which the evaluating unit comprises a limit switch providing a switching signal at the end of the measurement interval and at least one time interval corresponding to the measuring time within the measuring time interval. It is constructed from a sub-switch providing a switch signal when reaching a value proportional to time, The programmable inputs of the sub-switch (s) and the limit switch are connected in parallel to each other for output of the counter and to adjust the value to be compared with the counter pulses; a parallel input and a programmable input for adjusting the measurement time within the time interval and the consumers It has control output outputs of the actuator for complete shutdown, and the time base circuit wiper input of the counter and evaluator unit is connected to a relay from the power supply meter that indicates the end of the measurement intervals.

Automatic switching between the various modes is also provided by the preferred embodiment, in which the dough switch (s) and the limit switch are provided with two different programmable inputs for adjusting the values to be compared with the counting pulses, and a day switch (mode switch) input for selecting them. which are connected to a relay from the electricity meter's power meter, which is operated by a signal issued at peak consumption.

In a further preferred embodiment, the counted consumption pulses within the measurement time interval and / or the time elapsed since the beginning of the measurement can be displayed, wherein the counter output and the time base circuit output are connected to a display via a data selector and a data selector control input. earth is connected via a switch.

Is a preferred embodiment of the limit switch of the evaluation unit used in the device according to the invention? It consists of a single element, one for writing and one for actuating an input signal, deleting an input signal, preferably an RS memory, and a logical evaluation network connected to the input of the memory for comparing two preprogrammed values with the output of the counter. The evaluation network is composed of a gate circuit with a logic AND connection with a diode network, suitable for comparing the two programmable values, preferably a NAND gate, where the diodes are connected at their anode to the gate circuit input, the outputs of the counter are binary programmable, and earth-potential switch contacts are directly connected to the diode network-22

189 857.

The storage wiper input is connected via an inverter to the contact of a relay earth potential switch that supplies a signal indicating the end of the measurement time intervals, if any.

A preferred embodiment of the sub-switches of the evaluation unit used in the apparatus according to the invention comprises a second logical network for storing the logic network for evaluating the signals of the time base circuit, including an input and an eraser output. connected to the blocking input of the logic networks connected to the input of the first storage element for comparing the pre-programmed values and the consumption pulses at the outputs of the counter, the output of the logic network evaluating the signals of the time base circuit to the input input of the second storage element; a transmitter relay is optionally connected via an inverter which is also connected to the wiper input of the first storage element. The logic network evaluating the signals of the time base circuit comprises a gate circuit implementing a logical AND connection with a diode network, preferably a NAND gate, where the diodes are connected at their anode to the gate circuit input and the outputs of the time base circuit are binary programmable .

The invention will now be described in more detail with reference to the exemplary embodiments shown in the accompanying drawings, in which:

Fig. 1 illustrates a consumption function illustrating the measurement principle of a device according to the invention, a

FIG. 2 is a time diagram of pulses providing input signals to the device of the present invention, a

Figure 3 is a schematic diagram of an exemplary embodiment of the device of the invention, a

Figure 4 is a schematic schematic diagram of a preferred embodiment of the limit switch used in the device of the present invention, and

Fig. 5 is a schematic diagram of a preferred embodiment of a sub-switch of the device of the present invention.

Figure 1 shows an ideal consumption curve 1 and a realistic consumption curve 2 controlled by the device according to the invention. Ideally constant and consumption value of the active power reaches a hundred percent of the allocated consumption value by the end of the quarter-hour measuring interval, thus one the ideal consumption curve is a straight line started from the origin and respectively pass through the Ti, W _t, t2, W, and ti5, W _t points. ^{1 3}

R ^s 2 consumption curve reflecting the real situation also starts from the origin but, for example greater because of the on consumers greater power ramp would result without this regulation or intervention to the actual effective metering of the quarter-hour measurement reaches the contracted quarter of an hour value and within a time interval of by the end of the quarter. By using a single control point, reaching the maximum (committed) value can only be avoided by switching off all consumers at the same time. This may also mean switching off consumers whose message cannot or should not be interrupted. In Figure 1, breakpoints 3 and 4 indicate, for example, the timing of two further interventions and controls, when it is necessary to switch off only a portion of the consumer to avoid the risk of overconsumption.

The pulse sequences shown in Fig. 2 are produced by the power supply meter in the form of alternating high voltage pulse packets which, by operation of relays, produce switching signals controlling the apparatus of the present invention. From a tariff point of view, there are two distinctive periods of daily consumption, daytime and peak, for which users usually assign different values in their electricity contract. In the figure, for the sake of illustration, the daytime tariff time is from six o'clock in the morning to 22.00 in the afternoon, from 12.00 in the afternoon to eighteen in the afternoon. Night consumption is not subject to a tariff distinction from daytime tariffs in accordance with current regulations.

A series of 8 pulses indicating the beginning and end of the quarter-hour measurement time intervals provides a quarter-hour switch signal by actuating a wiper relay. These 8 pulse series ensure synchronous operation of the power supply and the consumption meter. A series of pulses 9 with a frequency proportional to consumption is provided by a switch signal taken at a revolution from the power meter's rotary dial.

The left side of Figure 3 shows the relays that produce the pulse sequences shown in Figure 2. The embodiment of the maximum value monitoring device according to the invention shown in Fig. 3 comprises a counter 13 for consumption pulses, a time base circuit 14 suitable for measuring time within the measuring interval, two partial switches 15 and a limit switch 16 connected to the outputs 17 of the switches and limit switches. It has 18 intervention organs. A data selector output 21 is connected to the input 20 of the optional display 19. The data selector input 23 is connected to the output 25 of the counter 13 and the input 24 is connected to the output 26 of the time base circuit 14. A ground potential is connected to the control input of the data selector 21 via switch K. The output 25 of the counter 13 is connected to the parallel switch inputs 15, the limit switch 16 and the data selector 21, and the output 26 of the time base circuit 14 is connected to the parallel switch 24 inputs 15 and 21. The diode switch relay contacts 10 are connected to the sub switch 15 and the limit switch 16 to the diode switch 27 and 28, and the wiper relay earth potential switch contacts are connected to the charging input T of the sub switches 15, 16, 13 and timer 14. The sub-switches 15 and the limit switch 16 are provided with a programmable input 29 for daytime consumption and a programmable input 30 for peak time consumption. The sub-switches 15 are also provided with programmable inputs 31 for adjusting part-time intervention within the quarter-hour measurement time interval.

Prior to commissioning of the device according to the invention, the programmable inputs 29 and 30 of the limit switch for day and peak adjustment must be configured with the quarter-hour consumption values contracted with the utility. The 15th part-31

The actuation time of the 189,857 switches is set at the programmable inputs 31, and the consumption values for the actuation (within the quarter-hour measurement interval) are set at the programmable inputs 29 and 30. The adjustment can be made using binary programmable switches, preferably BCD switches (D1L microswitches or flanged switches). Upon power-up, the device is reset, i.e. the counter 13 and timer circuit 14 are reset, and the sub-switches 15 and limit switch 16 are reset. When reset switch 15 and limit switch 16 are reset, the actuators and / or switches actuated by the actuators 18 will be in a state such that no alarm is triggered or all consumers are switched on. The wipe issued by the wiper relay 11 every quarter hour produces the same basic position. Thus, after the quarter-hour wipe has been issued or turned on, the counter 13 is reset, the value displayed at its output equaling the number of consumption pulses to its input until the next quarter-hour wipe is received. If the counter is selected with the data selector, this value can also be read from the display 19 and monitored until the end of the quarter-hour measurement interval. An exemplary 12 V 50 Hz time base circuit 14 measures the time elapsed in minutes during quarter-hour measurement periods. This value, i.e. the time elapsed since the beginning of the measurement within the quarter hour time interval, can be read from the display 19 if the time base circuit 14 is selected for the data selector 21. By using two displays, the values displayed at the output of the counter and the time base circuit can be displayed simultaneously. In this case, the data selector 21 is not required. The sub-switches 15 only monitor the consumption pulses from the output 25 of the counter 13 to the parallel inputs 23 until the set times for the programmable inputs 31 have elapsed. If the number of counted consumption pulses reaches the value selected by the programmable inputs 27 or 28 before the time-out, the actuator actuator signal 18 will be output. As a result, some consumers are disconnected from the network and a warning signal is issued. The pre-programmed values are selected according to the time of day by the signal from the contacts of the 10-day relay relay. If the time elapsed since the beginning of the measurement reaches the time set at the programmable input 31, then the sub-switches 15 are disabled for further evaluation of the consumption pulses or for actuating the actuator signal. In the limit switch this cannot be disabled within the measuring time interval, so the limit switch can operate the actuator connected to its output 17 at any time until the quarter-hour wipe is received, provided that the pre-programmed quarterly average number of pulses counted by. The 18 actuator-controlled actuators result in the disconnection of all consumers connected to the network, while the partial actuator actuators disconnect only a portion of the consumers. In the vast majority of cases the limit switch operation can be avoided by switching off all consumers. This will re-connect the disconnected consumers to the network during the quarter hour measurement period.

4 is an exemplary embodiment of the limit switch used in the apparatus of the present invention from a single RS storage device having a writer and a wipe input, and a logic connected to the input of the recorder to compare the preprogrammed values to the output of the counter. An evaluation network 41 is constructed in which the evaluation network consists of a gate circuit which combines two programmed values and which is a logical AND connection with a diode network, in this case a NAND gate 42, where the diodes 43 are connected at their anode to the NAND gate input. and the counter outputs are connected to a diode network via binary programmable switches 44. The wiper input R of the RS storage 40 is connected via inverters to the contact of a wiper relay field potential switch 11 that indicates the end of the measurement time intervals. The earth contact switch contacts of the relay switch 10 are also connected to the diode network.

When switched on, a negative impulse is applied to the wipe input R of the RS storage 40, which clears the storage and thereby resets the actuator coupled to the output of the storage, which in this case is comprised of a relay and a transistor operating it. By default, the consumer connected to the actuator is connected to the network and the alarm indicators are also reset, ie they do not signal. The negative impulse on the input S of the RS memory 40 writes to the actuator the actuator, which disconnects the connected consumers (all consumers in the event of a limit switch) from the network and actuates the alarm signaling device. is provided by one of the two 42 NAND ports of the network. The low (logic 0 ”) level displayed at the output of any NAND gate writes the RS storage because the 45 diodes connected to the outputs and connected to their anode provide a logical OR connection to the low levels. And one of the 42 NAND gates will provide a negative impulse when the network input of each diode is high, because the diodes shared at their anode provide a logical AND connection to high levels. The values of the diurnal consumption can be set by means of binary programmable switches connected between the meter outputs and the cathodes of the diodes. During programming, switches that are connected to the counting outputs that have a high (logical j) level when reaching the value of the committed effective power must be closed. Programming can be done according to the format of the value displayed at the counter outputs, ie in pL BCD code. The time of day is selected by the earth contact switch of the relay relay, also connected to the diode network, by the time of day. Which NAND gate has a fbld potential from the contact via diode 43 is disabled and the other is enabled. As noted above, the comparative function of the evaluating network 41 in the present invention is accomplished by NAND gates with a diode network and binary programmable switches, which results in a very simple solution.

Figure 5 is a schematic diagram of an embodiment of a sub-switch of the present invention which, in addition to elements of the same design as the limit switch of Figure 4, is a logical logic of a second RS storage 46 and a NAND gate with diode network also includes a network. The wiper inputs of the two RS storage wires are interconnected and connected to the side potential switch contact of wiper relay 11. The output Q of the second RS storage 46 is connected to the blocking input L of the logical evaluation network 41 for comparing the pre-programmed values with the consumption pulses at the counter outputs.

The sub-switch is reset when the power is turned on, similarly to the limit switch, ie, the RS memory is cleared by a negative pulse on the R wiper inputs. As a result, the evaluation network is disabled, the disconnected consumers are re-connected to the network, and the alarm signaling is terminated. Setting the split time from the start of the measuring time interval and comparing the value at the output of the time base circuit with the set value in the embodiment shown in the figure is the same as programming and comparing the consumption values. If frequent reprogramming of the part time is not required, the programming switches 50 may be replaced by fixed junctions. In fixed programming, the diodes without bridging 40 can be omitted, or instead of bridging, the programming can be done by soldering the diodes to the correct position. These programming options can, of course, be used in the programming of the consumption values in both the limit switch and the sub switches.

Advantageous effects of using the device of the present invention can be summarized as follows: The device is simple in circuitry and therefore inexpensive, yet highly reliable. In addition to the use of digital technology, its reliability is also enhanced by full synchronization with the power supplier's main meter. Its simple operation, which requires no expertise or supervision, ensures preprogramming and automatic switching of programmed values.

Claims (5)

1. A programmable maximum value monitor, preferably based on the measurement of the average effective power consumption of simultaneous power consumption of power consumption sites, based on a power contract, which is provided with a counter receiving pulses from the electricity meter's consumption meter, one time measurement unit, an actuator comprising a switch and / or signaling means coupled to the output of the evaluation unit, characterized in that the evaluation unit comprises a limit switch (16) providing a switching signal when the maximum value is reached at the end of the measuring time interval and at least one Sub - switch providing a switching signal when a time - proportional value is reached a lead (15) is constructed; a programmable input (29, 30) connected in parallel to the partial switch (s) (15) and the limit switch (16) connected to the output (25) of the Counter (13) and to adjust values to be compared with the counter pulses, and a parallel input (24) of the sub-switch (s) (15) receiving the output (26) of the time base circuit (14) and a programmable input (31) for adjusting the measurement time within the time interval and an actuator for partially or completely switching off the consumers. and the wiper input of the time base circuit (14), the counter (13), and the evaluation unit are connected to the wipe relay (11) from the power supply meter that indicates the end of the measurement intervals. Device according to Claim 1, characterized in that the partial switch (s) (15) and the limit switch (16) have two different programmable inputs (29, 30) for adjusting the values to be compared with the counting pulses, and a time switch for selecting them. they are also provided with inputs (27, 28) which are connected to a diode switch relay (10) from the power meter's power meter, which is operated by a signal being output at peak consumption. Apparatus according to claim 1 or 2, characterized in that it has a display (19) for indicating the pulse consumption and / or elapsed measurement time counted in the measuring time intervals, and an output (13) of the counter (13). 25) and the output (26) of the time base circuit (14) is connected to the display (19) via a data selector (21) and to the control input of the data selector (21) via a switch (K). Device according to Claim 1 or 2, characterized in that the limit switch (16) comprises a single storage element having an entry and an erase input (S, R) providing an actuation signal, preferably an RS storage (40) and two pre-programmed values. includes a logic kl evaluation network (41) connected to the input (25) of the counter (13) and a logic AND connection with the diode network, a gate circuit for comparing a programmable value, preferably a NAND gate (42), wherein the diodes (43) are connected at their anode to the gate circuit input, the output (13) of the counter (13) is connected directly to the diode network , to the container wiper input (R) ped Until inverters, the ground potential switch contacts of the wipe relay relay (11) which signal the end of the measurement time intervals are connected via inverters. Apparatus according to claim 1 or 2, characterized in that, in addition to the components of the sub-switches (15) having the same structure as the limit switch (16), a logic network (47) evaluating the signals of the time base circuit (14) and and a storage element having an erasure input, preferably an RS container (46) 189,857 disable output (Q) is connected to the disable input (L) of the evaluating logic networks connected to the input of the first storage element comparing the preprogrammed values to the output pulses of the outputs of the counter (13); (14), the output of the logic network (47) evaluating the signals, and the wiper input (R) of the wiper input (R) is optionally connected via an inverter which is also connected to the wiper input (R) of the first storage element. connected, the logic network (47) for evaluating the signals of the time base circuit comprises a gate circuit implementing a logical AND connection with a diode network, preferably a NAND gate (48), wherein the outputs of the diode (49) are binary programmable switches (50) cathode of the diodes (49) are connected.